Accelerated design and optimization of battery management systems using HIL simulation and Rapid Control Prototyping

2012 IEEE International Electric Vehicle Conference Pub Date : 2012-03-04 DOI:10.1109/IEVC.2012.6183235

R. Subramanian, P. Venhovens, B. Keane

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引用次数: 15

Abstract

This paper describes the use of Hardware-in-Loop (HIL) simulation and Rapid Control Prototyping (RCP) tools for the accelerated design and optimization of battery management systems (BMS) typically found in hybrid/electric vehicles. The BMS is an electronic system that manages a rechargeable battery pack. Its functions include monitoring the cell/pack voltage, current, temperature, state-of-charge, depth-of-discharge, and state-of-health. Besides reporting this data to a supervisory (powertrain) controller, the BMS protects the battery by preventing it from operating outside its safe operating range and balancing the individual cells. Programming, testing and validation of the BMS with real batteries is a time-consuming, expensive and potentially dangerous operation since physical batteries needs to be discharged and re-charged for every development iteration. With the help of virtual batteries models as part of a HIL simulation, the BMS algorithm can be developed, calibrated and validated in a very secure and time-efficient manner resulting in a significant product development time reduction.

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使用HIL仿真和快速控制原型加速设计和优化电池管理系统

本文介绍了使用硬件在环(HIL)仿真和快速控制原型(RCP)工具来加速设计和优化电池管理系统(BMS)，通常用于混合动力/电动汽车。BMS是一个管理可充电电池组的电子系统。它的功能包括监测电池/电池组电压、电流、温度、充电状态、放电深度和健康状态。除了将这些数据报告给监督(动力系统)控制器外，BMS还通过防止电池超出其安全工作范围和平衡单个电池来保护电池。使用真正的电池对BMS进行编程、测试和验证是一项耗时、昂贵且潜在危险的操作，因为每次开发迭代都需要对物理电池进行放电和充电。借助虚拟电池模型作为HIL仿真的一部分，可以以非常安全和省时的方式开发、校准和验证BMS算法，从而显著缩短产品开发时间。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2012 IEEE International Electric Vehicle Conference

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